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System Administration Guide: IP Services     Oracle Solaris 10 8/11 Information Library
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Document Information


Part I Introducing System Administration: IP Services

1.  Oracle Solaris TCP/IP Protocol Suite (Overview)

Part II TCP/IP Administration

2.  Planning Your TCP/IP Network (Tasks)

3.  Introducing IPv6 (Overview)

4.  Planning an IPv6 Network (Tasks)

5.  Configuring TCP/IP Network Services and IPv4 Addressing (Tasks)

6.  Administering Network Interfaces (Tasks)

7.  Configuring an IPv6 Network (Tasks)

8.  Administering a TCP/IP Network (Tasks)

9.  Troubleshooting Network Problems (Tasks)

10.  TCP/IP and IPv4 in Depth (Reference)

What's New in TCP/IP and IPv4 in Depth

TCP/IP Configuration Files

/etc/hostname.interface File

/etc/nodename File

/etc/defaultdomain File

/etc/defaultrouter File

hosts Database

/etc/inet/hosts File Format

Initial /etc/inet/hosts File

How Name Services Affect the hosts Database

ipnodes Database

netmasks Database

What Is Subnetting?

Creating the Network Mask for IPv4 Addresses

/etc/inet/netmasks File

inetd Internet Services Daemon

Network Databases and the nsswitch.conf File

How Name Services Affect Network Databases

nsswitch.conf File

Changing nsswitch.conf

bootparams Database

Wildcard Entry for bootparams

ethers Database

Other Network Databases

networks database

protocols Database

services Database

Routing Protocols in Oracle Solaris

Routing Information Protocol (RIP)

ICMP Router Discovery (RDISC) Protocol

Network Classes

Class A Network Numbers

Class B Network Numbers

Class C Network Numbers

11.  IPv6 in Depth (Reference)


12.  About DHCP (Overview)

13.  Planning for DHCP Service (Tasks)

14.  Configuring the DHCP Service (Tasks)

15.  Administering DHCP (Tasks)

16.  Configuring and Administering the DHCP Client

17.  Troubleshooting DHCP (Reference)

18.  DHCP Commands and Files (Reference)

Part IV IP Security

19.  IP Security Architecture (Overview)

20.  Configuring IPsec (Tasks)

21.  IP Security Architecture (Reference)

22.  Internet Key Exchange (Overview)

23.  Configuring IKE (Tasks)

24.  Internet Key Exchange (Reference)

25.  IP Filter in Oracle Solaris (Overview)

26.  IP Filter (Tasks)

Part V Mobile IP

27.  Mobile IP (Overview)

28.  Administering Mobile IP (Tasks)

29.  Mobile IP Files and Commands (Reference)


30.  Introducing IPMP (Overview)

31.  Administering IPMP (Tasks)

Part VII IP Quality of Service (IPQoS)

32.  Introducing IPQoS (Overview)

33.  Planning for an IPQoS-Enabled Network (Tasks)

34.  Creating the IPQoS Configuration File (Tasks)

35.  Starting and Maintaining IPQoS (Tasks)

36.  Using Flow Accounting and Statistics Gathering (Tasks)

37.  IPQoS in Detail (Reference)



Routing Protocols in Oracle Solaris

This section describes two routing protocols supported in Oracle Solaris: Routing Information Protocol (RIP) and ICMP Router Discovery (RDISC). RIP and RDISC are both standard TCP/IP protocols. For complete lists of routing protocols available in Oracle Solaris, refer to Table 5-1 and Table 5-2.

Routing Information Protocol (RIP)

RIP is implemented by in.routed, the routing daemon, which automatically starts when the system boots. When run on a router with the s option specified, in.routed fills the kernel routing table with a route to every reachable network and advertises “reachability” through all network interfaces.

When run on a host with the q option specified, in.routed extracts routing information but does not advertise reachability. On hosts, routing information can be extracted in two ways:

ICMP Router Discovery (RDISC) Protocol

Hosts use RDISC to obtain routing information from routers. Thus, when hosts are running RDISC, routers must also run another protocol, such as RIP, in order to exchange router information.

RDISC is implemented by in.routed, which should run on both routers and hosts. On hosts, in.routed uses RDISC to discover default routes from routers that advertise themselves through RDISC. On routers, in.routed uses RDISC to advertise default routes to hosts on directly-connected networks. See the in.routed(1M) man page and the gateways(4) man page.